KR100784220B1 - A coil of electromagnetic - Google Patents

Abstract

An electromagnetic coil is provided to stably operate an electromagnet by winding a plurality of aluminum wires simultaneously for identifying the calorific value of each wire without a temperature deviation. An electromagnetic coil includes an insulating material(800), first and second wires(402,404), a coating layer(802), and a bobbin. The first and the second wires are coated with the insulating material. The coating layer has an insulating property by encompassing the first and the second wires in parallel with each other for binding the first and the second wires as a single wire. The single wire of the first and the second wires is wound around the bobbin.

Description

A coil of electromagnetic

1 is a cross-sectional view showing a partial configuration of the clutch provided in the compressor,

2 is a view showing a state in which a wire rod of copper material is wound on a bobbin;

3 is a view showing the configuration of an embodiment of winding an aluminum wire to the bobbin according to the present invention,

4 is a view showing a connection state of the first wire and the second wire of aluminum material wound on the bobbin in the present invention,

5 is a view showing the configuration of another embodiment of winding the wire rod of aluminum material in accordance with the present invention,

6 is a view showing the configuration of another embodiment of winding an aluminum wire in the bobbin according to the present invention,

7 is a view showing a state in which the first wire and the second wire coated with an insulating material are bonded to each other according to the present invention as an example.

Explanation of symbols for the main parts of the drawings

400: bobbin 402: first wire rod

404: second wire rod 800: insulating material

802: coating layer

The present invention relates to an electromagnet coil used in a clutch for a compressor of a vehicle.

In general, a vehicle is equipped with an air conditioner for air conditioning in the room. The air conditioner compresses the heat exchange medium at high temperature and high pressure with a compressor, and supplies the compressed heat exchange medium to the heat exchanger to cool the interior of the vehicle.

The compressor is driven by the power of the engine of the vehicle and includes a clutch to transmit or block the driving force of the engine to the compressor. That is, when the clutch is driven, the driving force of the engine is transmitted to the compressor to be driven, and when the clutch is not driven, the driving force of the engine is not transmitted to the compressor so as not to be driven.

1 is a partial cross-sectional view showing the configuration of a clutch provided in the compressor. Here, reference numeral 100 denotes a compressor body. On the rotating shaft 100a of the compressor main body 100, a pulley 102 coupled with a bearing is rotatably installed. The pulley 102 is connected to the engine by a belt (not shown) so that the pulley 102 is rotated when the engine is driven.

In addition, an electromagnet 104 fixed to the compressor main body 100 is positioned on the pulley 102, and a friction surface 102a is formed on the front surface of the pulley 102.

The hub 106 is fixed to the end of the rotating shaft 100a of the compressor main body 100, and the stopper plate 108 is coupled to the tip of the hub 106. The disk 110 is installed on the rear surface of the stopper plate 108 to be spaced apart from the friction surface 102a of the pulley 102 by a predetermined distance.

The clutch having such a configuration generates a magnetic force from the electromagnet 104 when a predetermined voltage is applied to the electromagnet 104 fixed to the compressor main body 100 so that the disk 110 has a friction surface 102b of the pulley 102. Close to) At this time, the leaf spring is fixed to the disk 110 and the other end is provided between the hub 106 and the stopper plate 108 has a restoring force.

As the friction surface 102b of the disk 110 and the pulley 102 comes into close contact with each other, the rotational force of the pulley 102 that is rotated by the engine of the vehicle causes the friction surface of the disk 110 and the pulley 102 ( Through the friction force between 102b, it is transmitted to the rotating shaft (100a) of the compressor to drive the compressor body (100).

On the other hand, when no voltage is applied to the electromagnet 104, the magnetic force is removed so that the friction surface 102b of the pulley 102 and the disk 110 is separated by the restoring force of the leaf springs, the rotational force of the pulley 102 It is not transmitted to the rotating shaft 100a of the compressor main body 100, and the pulley 102 is idle.

In this clutch, the electromagnet 104 is a bobbin 300 of the coil housing made of plastic, which is an insulating member, as shown in FIG. 2, and typically a copper wire 302 having excellent conductivity. Is coated with an insulating material such as enamel. Then, the coated copper wire is wound around the bobbin 300 in a threaded fashion to form a predetermined number of times.

However, the electromagnet 104 has a problem in that copper is expensive as winding the wire rod made of a copper material having excellent conductivity, thereby increasing the manufacturing cost of the clutch for the compressor.

In more detail, in general, the electrical conductivity of metals is in the order of silver> copper> gold> aluminum> magnesium> zinc> iron> lead> antimony. Silver has the best electrical conductivity, but silver is very expensive compared to copper.

Therefore, after the silver, a coil of the electromagnet 104 is manufactured by using a copper wire having excellent electrical conductivity and low resistivity and low heat generation rate.

However, Korea is mostly dependent on imports of copper, and is suffering from the cost problem caused by strong copper demand and price fluctuations in the metal market, as well as electromagnet coils made of copper wire and There was a problem that the linkage to the manufacturing cost of the clutch for the compressor rises.

Therefore, in order to solve the cost problem of copper wire as an electromagnet coil, aluminum is used as the electromagnet coil which is very inexpensive compared to copper.

When the wire rod of the aluminum material is used as a coil, the electromagnet may be manufactured at a relatively low cost as compared with the case of using copper. However, aluminum has lower electrical conductivity than copper, so in order for the electromagnet to generate magnetic force of the same strength, the number of turns should be increased when using aluminum wire compared with copper wire. There was a problem that becomes large.

That is, in the case of manufacturing an electromagnet by winding an aluminum wire having the same thickness as the copper wire and the number of windings in the bobbin, when the electrical conductivity of aluminum is lower than that of copper, the same level of voltage is applied. The amount of current flowing through the aluminum wire is less than the amount of current flowing through the copper wire, so that the magnetic force generated from the electromagnet using the aluminum wire is the strength of the magnetic force generated from the electromagnet using the copper wire. Lower than

Therefore, in order to have the same current value as the electromagnet used in the copper wire rod, the wire of aluminum wire should be wound about 40% or more than the wire of copper wire. Therefore, the electromagnet using the wire wire of aluminum wire is made of copper wire. It is bulkier than an electromagnet.

The voltage induced in the coil of the electromagnet is shown in Equation 1 below.

Where V is the voltage, L is the inductance of the electromagnet coil, B is the magnetic flux density, and t is the time.

When the voltage induced in the coil of the electromagnet is increased in Equation 1, the inductance of the electromagnet coil should be high, and the inductance of the electromagnet coil increases as the number of windings increases.

As such, when the aluminum wire is used instead of the copper wire as the coil of the electromagnet, the volume of the electromagnet coil is increased, and the volume of the compressor clutch is increased.

In recent years, as the price of copper continues to rise, efforts have been made to manufacture electromagnets using aluminum wires, and also efforts to solve the increase in volume when aluminum wires are used. I'm doing it.

As an example, in order to solve a volume problem that increases when an aluminum wire is used rather than when a copper wire is used, a technology for manufacturing and accommodating a compressor clutch has been proposed.

However, deformation of the clutch for the compressor can solve some of the increase in volume, but when the aluminum wire is used, the resistance value is increased by about twice as compared to the case of using a copper wire, a lot of heat was generated.

That is, in the case of using the aluminum wire rod as described above, in order to obtain the same current value as in the case of using the copper wire rod, it must be wound more than the copper wire rod. As the length of the aluminum wire becomes longer, the resistance value increases together, and as the resistance value increases, a lot of heat is generated to solve the heat generation problem.

An object of the present invention is to provide an electromagnet coil that can solve the heating problem by reducing the resistance value in using an aluminum wire as the electromagnet coil.

According to the present invention having this object, a plurality of wire rods of aluminum material are wound around the bobbin, and the plurality of wire rods of the wound aluminum material are connected in parallel to each other. Therefore, in the case of using aluminum wires, even if the volume is increased by winding more than in the case of using copper wires, the resistance value decreases as the plurality of wires of aluminum material are connected in parallel to each other. The heat generated by the electromagnet can be reduced.

In the winding of a plurality of wire rods of aluminum material to the bobbin, the windings are not sequentially wound and simultaneously wound, so that the heat dissipation amount of each of the wire rods of aluminum material is the same, and the temperature deviation does not occur, so that the performance in the saturated state is the same. Done.

Therefore, the electromagnet coil of the present invention is made of a plurality of wire rods of aluminum material wound on the bobbin, characterized in that the plurality of wire rods of the wound aluminum material are connected in parallel to each other.

The winding of the plurality of wire rods of aluminum material is characterized in that the winding of the plurality of wire rods of aluminum material in parallel.

The following detailed description is only illustrative, and merely illustrates embodiments of the present invention. In addition, the principles and concepts of the present invention are provided for the purpose of explanation and most useful. Accordingly, various forms that can be implemented by those of ordinary skill in the art, as well as not intended to provide a detailed structure beyond the basic understanding of the present invention through the drawings.

Figure 3 is a view showing the configuration of an embodiment of winding a plurality of wires of aluminum material on the bobbin according to the present invention. Here, reference numeral 400 denotes a bobbin made of a plastic material that is an insulating member. The bobbin 400 is wound around a first wire 402 made of aluminum coated with an insulating material, such as enamel, and a second wire made of aluminum coated with an insulating material, such as enamel, on the outer side of the wound first wire 402. 404 is wound.

As shown in FIG. 4, the first wire 402 and the second wire 404 are connected in parallel to each other.

In the present invention configured as described above, the first wire 402 and the second wire 404 made of aluminum are sequentially wound on the bobbin 400, and the first wire 402 and the first made of aluminum are sequentially wound. Since the two wires 404 are connected in parallel to each other, the composite resistance values of the first wire 402 and the second wire 404 decrease as shown in Equation 2.

For example, assuming that the resistance values of the first wire rod 402 and the second wire rod 404 are the same, when the first wire rod 402 and the second wire rod 404 are connected in parallel, the resistance value is 1 /. Decreases to two.

However, when the first wire 402 and the second wire 404 is wound by the same number of times as shown in FIG. 3, the resistance value of the second wire 404 is higher than that of the first wire 402. Becomes high. That is, since the first wire 402 is wound on the bobbin 400 first, and then the second wire 404 is wound, the first wire rod when the first wire rod 402 and the second wire rod 404 have the same number of turns. The length of the second wire rod 404 is longer than the length of 402, so that the resistance value of the second wire rod 404 is higher than that of the first wire rod 402.

Therefore, when the electromagnet is driven by applying a voltage to the first wire rod 402 and the second wire rod 404, the heat generation amount of the first wire rod 402 and the heat generation amount of the second wire rod 404 are different, resulting in a temperature deviation. Due to the temperature deviation, the performances in the saturated state are different from each other, so that the electromagnets cannot be operated stably.

Figure 5 is a view showing the configuration of another embodiment of winding an aluminum wire to the bobbin according to the present invention. As shown therein, another embodiment of the present invention divides the region of the bobbin 400 into two, and each of the divided regions includes a first wire 402 and a second wire made of aluminum coated with an insulating material such as enamel. Each of the 404 is wound, and the first wire 402 and the second wire 404 made of aluminum are connected in parallel.

According to another embodiment of the present invention configured as described above, when the first wire 402 and the second wire 404 are wound the same number of times, the resistance values of the first wire 402 and the second wire 404 are the same. .

However, if it is assumed that the first wire rod 402 is located inward and the second wire rod 404 is located outward, the first wire rod 402 located inside does not have good heat dissipation due to poor air flow, The second wire 404 is located in the air flow is good heat radiation is good.

Then, the temperature difference occurs between the first wire rod 402 and the second wire rod 404, and the saturation performance of the first wire rod 402 and the second wire rod 404 are different from each other, which adversely affects the performance of the electromagnet. .

Figure 6 is a view showing the configuration of another embodiment of winding an aluminum wire to the bobbin according to the present invention. As shown therein, another embodiment of the present invention places the first wire 402 and the second wire 404 made of aluminum in parallel to each other, and simultaneously winding the bobbin 400. Then, both ends of the wound first wire 402 and the second wire 404 are connected to each other and connected in parallel.

In order to simultaneously wind the first wire rod 402 and the second wire rod 404 to the bobbin 400, the first wire rod 402 and the second wire rod 404 are coupled to each other in parallel to the bobbin 400. It is preferable to wind.

For example, as shown in FIG. 7, the first wire 402 and the second wire 404 made of aluminum coated with an insulating material 800 such as enamel are wrapped in an insulating coating layer 802 in parallel with each other. A single wire rod is combined, and the combined first wire rod 402 and the second wire rod 404 are wound around the bobbin 400.

In another embodiment of the present invention configured as described above, since the first wire 402 and the second wire 404 are made of aluminum at the same time, the resistance values of the first wire 402 and the second wire 404 are the same. do.

When the voltage is supplied to the first wire rod 402 and the second wire rod 404 to operate, the heat generation amounts of the first wire rod 402 and the second wire rod 404 are the same, and the heat dissipation amount is also the same.

The temperature difference does not occur between the first wire rod 402 and the second wire rod 404, and the electromagnet operates stably.

In the above description, the winding of only the first wire 402 and the second wire 404 made of aluminum to the bobbin 400 has been described as an example. In carrying out the present invention, two or more wire rods may be simultaneously wound on the bobbin 400, and the wire rods of the present invention may be wired in parallel to be modified in various ways.

As described in detail above, the present invention winding a plurality of wire rods of aluminum material to the bobbin, and by connecting a plurality of wire rods of aluminum material in parallel, the total length of the aluminum material as compared to the case of using a wire rod of copper material In the case of using wires, the total length is long, so the resistance value is low even if the volume is increased, thereby reducing the heat generation amount.

In addition, rather than sequentially winding the plurality of wire rods made of aluminum, simultaneous winding of the plurality of wire rods of aluminum material generates the same amount of heat, and the heat dissipation is the same, and thus a temperature deviation of each of the wire rods of aluminum material occurs. If not, the electromagnet will operate stably.

The present invention has been described in detail with reference to exemplary embodiments, but those skilled in the art to which the present invention pertains can make various modifications without departing from the scope of the present invention. Will understand.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

Claims (6)

Windings on bobbins, consisting of a plurality of wires coated with insulating material on the surface, The wound wires are electromagnet coils, characterized in that connected in parallel with each other. The method of claim 1, The winding of the plurality of wire rods, the electromagnetic coil winding at the same time. The method according to claim 1 or 2, The plurality of wire rod, the electromagnet coil made of aluminum material. The method according to claim 1 or 2, Electromagnet coil for simultaneously winding the plurality of wires in parallel with each other in an insulating coating layer. Consists of a plurality of wires of aluminum wound on the bobbin and coated with insulation, The plurality of wires of the wound aluminum material is wound in parallel to the bobbin at the same time, the electromagnet coil, characterized in that the plurality of wires are connected in parallel with each other. The method of claim 5, Electromagnet coil for simultaneously winding the plurality of wires in parallel with each other in an insulating coating layer.

Images